• Title/Summary/Keyword: plasma assisted combustion

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Development of Plasma Assisted Burner for Regeneration of Diesel Particulate Filter (매연여과장치 재생을 위한 플라즈마 응용 버너 개발)

  • Cha, Min-Suk;Lee, Dae-Hoon;Kim, Kwan-Tae;Lee, Jae-Ok;Song, Young-Hoon;Kim, Seock-Joon
    • Journal of the Korean Society of Combustion
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    • v.12 no.4
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    • pp.8-13
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    • 2007
  • Plasma assisted combustion is an old subject for the combustion society, but recently, the subject is refocused partly because techniques for non-thermal plasmas are progressed significantly, and partly because there are lots of applications which need to be overcome by a new reaction technology. In the present study, we have developed plasma assisted burner (plasma burner), which can be used as a heating source in a diesel particulate filter system. The burner can burn 20-60 cc/min of diesel fuel with 50 lpm of fresh air in an exhaust pipe of 2.0 liter diesel engine. Using 20 cc/min of diesel fuel, an exhaust temperature for 2.0 liter diesel engine can be raised up to around $600^{\circ}C$ for a wide range of engine speed (idle-3,000 rpm). The characteristics of the plasma burner are reported, and the possible operating mechanism of it will be discussed based on the effects of an electric field and a plasma on flames.

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Development of Plasma Assisted Burner for Regeneration of Diesel Particulate Filter (플라즈마를 이용한 매연여과장치 재생용 버너 개발)

  • Cha, Min-Suk;Lee, Dae-Hoon;Kim, Kwan-Tae;Lee, Jae-Ok;Song, Young-Hoon;Kim, Seock-Joon
    • 한국연소학회:학술대회논문집
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    • 2007.05a
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    • pp.202-206
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    • 2007
  • Plasma assisted combustion is an old subject for the combustion society, but recently, the subject is refocused partly because techniques for non-thermal plasmas are progressed significantly, and partly because there are lots of applications which need to be overcome by a new reaction technology. In the present study, we have developed plasma assisted burner (plasma burner), which can be used as a heating source in a diesel particulate filter system. The burner can bum 20 - 60 cc/min of diesel fuel with 50 lpm of fresh air in an exhaust pipe of 2.0 liter diesel engine. Using 20 cc/min of diesel fuel, an exhaust temperature for 2.0 liter disel engine can be raised up to around $600^{\circ}C$ for the range of engine speeds is idle - 3,000 rpm. The characteristics of the plasma burner are reported, and the possible operating mechanism of it will be discussed based on the effects of an electric field and a plasma on flames.

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Numerical analysis of nonequilibrium plasma assisted combustion using OpenFOAM (OpenFOAM을 이용한 비평형 플라즈마 연소 수치해석)

  • Park, Yeongdo;Huh, Kang Y.
    • 한국연소학회:학술대회논문집
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    • 2015.12a
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    • pp.181-182
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    • 2015
  • The nonequilibrium plasmas in which electrons have much higher energy compared to heavy species that cannot be represented with single temperature can enhance combustion reaction significantly. Therefore the nonequilibrium plasmas provide new effective mechanism to control combustion to overcome difficulties advanced combustion devices exploiting extreme operating parameters for high efficiency, lower emission.

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A Study on a Combined DeNOx Process of Plasma Oxidation and $NH_3$ SCR for Diesel Engine (플라즈마 산화와 암모니아 SCR 복합탈질공정의 엔진적용 연구)

  • Song, Young-Hoon;Lee, Jae-Ok;Cha, Min-Suk;Kim, Seock-Joon;Ryu, Jeong-In
    • Journal of the Korean Society of Combustion
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    • v.12 no.4
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    • pp.39-46
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    • 2007
  • The technique of $NH_3$ SCR (selective catalytic reduction) assisted by plasma oxidation has been applied to a 2,000 cc diesel engine. The present combined $deNO_x$ process consists of two steps. The first step is that about 50% of emitted NO from the engine is oxidized to $NO_2$ in a plasma oxidation process. The second step is that NO and $NO_2$ are simultaneously reduced to $N_2$ in the $NH_3$ SCR process. The engine test results showed that the $deNO_x$ rates of the present combined process are higher than those of conventional SCR process by 20%. Such a high performance of the combined process is noticeable especially, when the exhaust temperature are relatively low, i.e., $170-220^{\circ}C$. To provide a feasibility of the present technique the effects of operating conditions, such as an electrical input energy, an exhaust gas temperature, an initial NO concentration, and the amount of hydrocarbon addition, were discussed.

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Nonthermal Plasma-assisted Diesel Reforming and Injection of the Reformed Gas into a Diesel Engine for Clean Combustion (디젤의 청정연소를 위한 저온 플라즈마 연료개질 및 개질가스의 디젤엔진 첨가에 관한 연구)

  • Kim, Seong-Soo;Chung, Soo-Hyun;Kim, Jin-Gul
    • Journal of Korean Society of Environmental Engineers
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    • v.27 no.4
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    • pp.394-401
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    • 2005
  • A nonthermal plasma-assisted fuel reformer was developed and the effects of operating variables on the performance of this reformer were studied. The $H_2$-rich reformed gas from the reformer was injected into a diesel engine under an idle condition and the effects of the amount of injected gas on the NO and soot reduction were investigated. It was found that with increasing electric power consumption, the degree of facility of ignition of the reforming reaction in the reformer could be enhanced. The performance of the reformer including $H_2$ concentration, $H_2$ recovery, and energy conversion was affected only by the O/C mole ratio. This was because the equilibrium reaction temperature was governed by the O/C mole ratio. With increasing O/C mole ratio, the $H_2$ recovery and energy conversion passed through the maximum values of 33.4% and 66%, respectively, at an O/C mole ratio between 1.2 and 1.5. The reason why the $H_2$ recovery and energy conversion increased with increasing O/C mole ratio when the O/C mole ratio was lower than $1.2{\sim}1.5$ appeared to be that the complete oxidation reaction occurred more enough with increasing O/C mole ratio in this low O/C mole ratio range and accordingly the reaction temperature increased. Whereas the reason why the $H_2$ recovery and energy conversion decreased with increasing O/C mole ratio when the O/C mole ratio was higher than $1.2{\sim}1.5$ appeared to be that the complete oxidation reaction was further advanced and the $H_2$ recovery and energy conversion decreased. As the weight ratio of reformed diesel to total diesel which entered the diesel engine was increased to $18.2{\sim}23.5%$, NO and soot reduction efficiencies increased and reached as values high as 68.5% and 23.5%, respectively.